A compression piston ring for an internal combustion engine, comprising a sliding surface formed by two ridges, upper and lower flank surfaces, and an inner circumferential surface, wherein the lower ridge runs at least in some regions parallel to the counter sliding surface and the upper ridge is designed as a taper faced Napier element.

7. Compression piston ring in accordance with claim 8, wherein the piston ring is a one-sided or two-sided wedge ring.

8. Compression piston ring for an internal combustion engine, the compression ring comprising a lower ridge and an upper ridge, each of the ridges including a sliding surface in contact with an opposing surface, wherein at least part of the sliding surface of the lower ridge is parallel to the opposing surface and builds up compression and the sliding surface of the upper ridge is at a defined angle to the opposing surface and a lower extremity of the sliding surface of the upper ridge comprises a chamfer so that it has a sharp-edged projection thereby forming a taper-faced Napier element, and at least the sliding surfaces are provided with a coating.

Description:

BACKGROUND OF THE INVENTION

The invention relates to a compression piston ring for an internal combustion engine.

DE 103 22 032 B3 discloses a compression piston ring for pistons in internal combustion engines or compressors with a sliding surface of an inner circumferential surface that has a groove, upper and lower flanks running therebetween, and an abutment formed by a slot. The groove is interrupted in the area of the abutment. The groove is provided with an undercut running towards the upper flank. The sliding surface is provided with a curved contour, wherein a heat-resistant coil spring is arranged in the area of the inner circumferential surface.

Known from DE 100 11 917 A1 is a piston ring for internal combustion engines having a wear-resistant coating that is applied using the PVD or CVD method and that is provided at least in the area of the sliding surface.

Compression rings today have the property of building up compression using their sliding surface geometry and when possible also of attaining a good scraping effect. It is not always possible to meet both requirements with one ring.

SUMMARY OF THE INVENTION

The underlying object of the invention is to provide a compression piston ring that satisfies the cited requirements, specifically building up compression and attaining a good scraping effect, using a new sliding surface configuration.

This object is attained using a compression piston ring for an internal combustion engine that includes a sliding surface formed by two ridges, upper and lower flank surfaces, and an inner circumferential surface, wherein the lower ridge runs parallel, at least in part, to an opposing sliding surface and the upper ridge is embodied as a taper-faced Napier element.

Advantageous refinements of the inventive subject-matter may be found in the subordinate claims.

The lower ridge is preferably embodied convex and may be symmetrically convex, relative to the ridge height.

In order to enhance the scraping effect, it is advantageous to provide the upper ridge with an inner chamfer.

According to another aspect of the invention, at least the two ridges of the compression piston ring are provided with a PVD layer, at least on the sliding surfaces thereof.

The inventive sliding surface configuration may be particularly advantageously employed in one or two-sided wedge type piston rings.

The inventive subject-matter is depicted in the drawing using an exemplary embodiment and is described as follows.

BRIEF DESCRIPTION OF THE DRAWING

The drawing is a cross sectional view of a compression piston ring of the invention.

The only FIGURE depicts part of the inventive compression piston ring 1. The compression piston ring 1 has two ridges 2, 3 that form the sliding surface. Furthermore, there is an upper flank surface 4 and a lower flank surface 5. In this example, the compression piston ring 1 is to be embodied as a wedge type piston ring provided with trapezoidal surfaces 6, 7. The ridge 3 is embodied slightly convex, while the ridge 2 is embodied with a taper-faced Napier element. The outer circumferential surface 3′ of the ridge 3 runs at least in part approximately parallel to an opposing sliding surface 8, while a taper-faced groove 2′ is worked in at a defined angle α to the opposing sliding surface 8 so that a relatively sharp-edged projection 9 that leads to a good scraping effect is formed. The ridge 3 builds up the compression. For further enhancing the scraping effect, an inner chamfer 10 is provided in the area of the projection 9. In this example, both ridges 2, 3 are provided with a sliding surface coating 11, 12 that was applied using the so-called PVD method.

Alternative sliding surface coatings for enhancing the wear-resistance of the sliding surfaces are also possible.